WIP: michelson_pair

This commit is contained in:
Lesenechal Remi 2020-04-18 00:02:33 +02:00
parent e94f445a51
commit 5bed9dadef
31 changed files with 240 additions and 85 deletions

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@ -15,8 +15,8 @@ let assert_equal_contract_type : check_type -> string -> Ast_typed.program -> As
| T_arrow {type1=args} -> (
match args.type_content with
| T_record m when LMap.cardinal m = 2 -> (
let param_exp = LMap.find (Label "0") m in
let storage_exp = LMap.find (Label "1") m in
let {field_type=param_exp;_} = LMap.find (Label "0") m in
let {field_type=storage_exp;_} = LMap.find (Label "1") m in
match c with
| Check_parameter -> assert_type_expression_eq (param_exp, param.type_expression)
| Check_storage -> assert_type_expression_eq (storage_exp, param.type_expression)

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@ -298,6 +298,19 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
ok (Some (String.uncapitalize_ascii ann), a))
aux node in
ok @@ snd m'
| T_record m when Ast_typed.Helpers.is_michelson_pair m ->
let node = Append_tree.of_list @@ Ast_typed.Helpers.tuple_of_record m in
let aux a b : type_value annotated result =
let%bind a = a in
let%bind b = b in
ok (None, T_pair (a, b))
in
let%bind m' = Append_tree.fold_ne
(fun (_, ({field_type ; michelson_annotation} : AST.field_content)) ->
let%bind a = transpile_type field_type in
ok (michelson_annotation, a) )
aux node in
ok @@ snd m'
| T_record m ->
let is_tuple_lmap = Ast_typed.Helpers.is_tuple_lmap m in
let node = Append_tree.of_list @@ (
@ -313,8 +326,8 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
ok (None, T_pair (a, b))
in
let%bind m' = Append_tree.fold_ne
(fun (Ast_typed.Types.Label ann, a) ->
let%bind a = transpile_type a in
(fun (Ast_typed.Types.Label ann, ({field_type;_}: AST.field_content)) ->
let%bind a = transpile_type field_type in
ok ((if is_tuple_lmap then
None
else
@ -448,7 +461,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
let%bind ty_lmap =
trace_strong (corner_case ~loc:__LOC__ "not a record") @@
get_t_record (get_type_expression record) in
let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap transpile_type ty_lmap in
let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap_t transpile_type ty_lmap in
let%bind path =
trace_strong (corner_case ~loc:__LOC__ "record access") @@
record_access_to_lr ty' ty'_lmap path in
@ -465,7 +478,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
let%bind ty_lmap =
trace_strong (corner_case ~loc:__LOC__ "not a record") @@
get_t_record (get_type_expression record) in
let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap transpile_type ty_lmap in
let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap_t transpile_type ty_lmap in
let%bind path =
trace_strong (corner_case ~loc:__LOC__ "record access") @@
record_access_to_lr ty' ty'_lmap path in

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@ -231,7 +231,7 @@ let rec untranspile (v : value) (t : AST.type_expression) : AST.expression resul
let%bind sub = untranspile v tv in
return (E_constructor {constructor=Constructor name;element=sub})
| T_record m ->
let lst = Ast_typed.Helpers.kv_list_of_record_or_tuple m in
let lst = List.map (fun (k,{field_type;_}) -> (k,field_type)) @@ Ast_typed.Helpers.kv_list_of_record_or_tuple m in
let%bind node = match Append_tree.of_list lst with
| Empty -> fail @@ corner_case ~loc:__LOC__ "empty record"
| Full t -> ok t in

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@ -182,6 +182,21 @@ let rec compile_type_expression (t:Raw.type_expr) : type_expression result =
ok @@ t_michelson_or ~loc a' b' c' d'
)
| _ -> simple_fail "michelson_or does not have the right number of argument")
| "michelson_pair" ->
let lst = npseq_to_list tuple.value.inside in
(match lst with
| [a ; b ; c ; d ] -> (
let%bind b' =
trace_option (simple_error "second argument of michelson_pair must be a string singleton") @@
get_t_string_singleton_opt b in
let%bind d' =
trace_option (simple_error "fourth argument of michelson_pair must be a string singleton") @@
get_t_string_singleton_opt d in
let%bind a' = compile_type_expression a in
let%bind c' = compile_type_expression c in
ok @@ t_michelson_pair ~loc a' b' c' d'
)
| _ -> simple_fail "michelson_or does not have the right number of argument")
| _ ->
let lst = npseq_to_list tuple.value.inside in
let%bind lst =

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@ -129,7 +129,8 @@ let rec compile_type_expression : I.type_expression -> O.type_expression result
let%bind record =
bind_map_list (fun (k,v) ->
let%bind v = compile_type_expression v in
ok @@ (k,v)
let content : O.field_content = {field_type = v ; michelson_annotation = None} in
ok @@ (k,content)
) record
in
return @@ O.T_record (O.LMap.of_list record)
@ -149,6 +150,13 @@ let rec compile_type_expression : I.type_expression -> O.type_expression result
(O.Constructor "M_right", {ctor_type = r ; michelson_annotation = Some r_ann}); ]
in
return @@ O.T_sum (O.CMap.of_list sum)
| I.T_operator (TC_michelson_pair (l,l_ann,r,r_ann)) ->
let%bind (l,r) = bind_map_pair compile_type_expression (l,r) in
let sum : (O.label * O.field_content) list = [
(O.Label "M_left" , {field_type = l ; michelson_annotation = Some l_ann});
(O.Label "M_right", {field_type = r ; michelson_annotation = Some r_ann}); ]
in
return @@ O.T_record (O.LMap.of_list sum)
| I.T_operator type_operator ->
let%bind type_operator = compile_type_operator type_operator in
return @@ T_operator type_operator
@ -177,7 +185,7 @@ and compile_type_operator : I.type_operator -> O.type_operator result =
| TC_arrow (i,o) ->
let%bind (i,o) = bind_map_pair compile_type_expression (i,o) in
ok @@ O.TC_arrow (i,o)
| TC_michelson_or _ -> fail @@ Errors.corner_case __LOC__
| TC_michelson_or _ | TC_michelson_pair _ -> fail @@ Errors.corner_case __LOC__
let rec compile_expression : I.expression -> O.expression result =
fun e ->
@ -587,7 +595,8 @@ let rec uncompile_type_expression : O.type_expression -> I.type_expression resul
let record = I.LMap.to_kv_list record in
let%bind record =
bind_map_list (fun (k,v) ->
let%bind v = uncompile_type_expression v in
let {field_type;_} : O.field_content = v in
let%bind v = uncompile_type_expression field_type in
ok @@ (k,v)
) record
in

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@ -9,6 +9,13 @@ let bind_map_cmap f map = bind_cmap (
ok {ctor with ctor_type = ctor'})
map)
let bind_map_lmap_t f map = bind_lmap (
LMap.map
(fun ({field_type;_} as field) ->
let%bind field' = f field_type in
ok {field with field_type = field'})
map)
type 'a folder = 'a -> expression -> 'a result
let rec fold_expression : 'a folder -> 'a -> expression -> 'a result = fun f init e ->
let self = fold_expression f in
@ -234,7 +241,7 @@ and map_type_expression : ty_exp_mapper -> type_expression -> type_expression re
let%bind temap' = bind_map_cmap self temap in
return @@ (T_sum temap')
| T_record temap ->
let%bind temap' = bind_map_lmap self temap in
let%bind temap' = bind_map_lmap_t self temap in
return @@ (T_record temap')
| T_tuple telst ->
let%bind telst' = bind_map_list self telst in

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@ -21,15 +21,17 @@ let rec idle_type_expression : I.type_expression -> O.type_expression result =
let record = I.LMap.to_kv_list record in
let%bind record =
bind_map_list (fun (k,v) ->
let%bind v = idle_type_expression v in
ok @@ (k,v)
let {field_type ; michelson_annotation} : I.field_content = v in
let%bind field_type = idle_type_expression field_type in
let v' : O.field_content = {field_type ; field_annotation=michelson_annotation} in
ok @@ (k,v')
) record
in
return @@ O.T_record (O.LMap.of_list record)
| I.T_tuple tuple ->
let aux (i,acc) el =
let%bind el = idle_type_expression el in
ok @@ (i+1,(O.Label (string_of_int i), el)::acc) in
ok @@ (i+1,(O.Label (string_of_int i), ({field_type=el;field_annotation=None}:O.field_content))::acc) in
let%bind (_, lst ) = bind_fold_list aux (0,[]) tuple in
let record = O.LMap.of_list lst in
return @@ O.T_record record
@ -254,8 +256,10 @@ let rec uncompile_type_expression : O.type_expression -> I.type_expression resul
let record = I.LMap.to_kv_list record in
let%bind record =
bind_map_list (fun (k,v) ->
let%bind v = uncompile_type_expression v in
ok @@ (k,v)
let {field_type;field_annotation} : O.field_content = v in
let%bind field_type = uncompile_type_expression field_type in
let v' : I.field_content = {field_type;michelson_annotation=field_annotation} in
ok @@ (k,v')
) record
in
return @@ I.T_record (O.LMap.of_list record)

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@ -12,6 +12,13 @@ let bind_map_cmap f map = bind_cmap (
ok {ctor with ctor_type = ctor'})
map)
let bind_map_lmap_t f map = bind_lmap (
LMap.map
(fun ({field_type;_} as field) ->
let%bind field' = f field_type in
ok {field with field_type = field'})
map)
type 'a folder = 'a -> expression -> 'a result
let rec fold_expression : 'a folder -> 'a -> expression -> 'a result = fun f init e ->
let self = fold_expression f in
@ -161,7 +168,7 @@ and map_type_expression : ty_exp_mapper -> type_expression -> type_expression re
let%bind temap' = bind_map_cmap self temap in
return @@ (T_sum temap')
| T_record temap ->
let%bind temap' = bind_map_lmap self temap in
let%bind temap' = bind_map_lmap_t self temap in
return @@ (T_record temap')
| T_arrow {type1 ; type2} ->
let%bind type1' = self type1 in

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@ -147,8 +147,9 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
| T_record m ->
let aux k v prev =
let%bind prev' = prev in
let%bind v' = evaluate_type e v in
ok @@ O.LMap.add (convert_label k) v' prev'
let {field_type ; field_annotation} : I.field_content = v in
let%bind field_type = evaluate_type e field_type in
ok @@ O.LMap.add (convert_label k) ({field_type ; michelson_annotation=field_annotation}:O.field_content) prev'
in
let%bind m = I.LMap.fold aux m (ok O.LMap.empty) in
return (T_record m)
@ -311,7 +312,7 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
ok (O.LMap.add (convert_label k) expr' acc , state')
in
let%bind (m' , state') = Stage_common.Helpers.bind_fold_lmap aux (ok (O.LMap.empty , state)) m in
let wrapped = Wrap.record (O.LMap.map get_type_expression m') in
let wrapped = Wrap.record (O.LMap.map (fun e -> ({field_type = get_type_expression e ; michelson_annotation = None}: O.field_content)) m') in
return_wrapped (E_record m') state' wrapped
| E_record_update {record; path; update} ->
let%bind (record, state) = type_expression e state record in
@ -323,7 +324,7 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
| T_record record -> (
let field_op = O.LMap.find_opt path record in
match field_op with
| Some tv -> ok (record,tv)
| Some {field_type=tv;_} -> ok (record,tv)
| None -> failwith @@ Format.asprintf "field %a is not part of record" O.PP.label path
)
| _ -> failwith "Update an expression which is not a record"

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@ -157,9 +157,10 @@ let rec untype_type_expression (t:O.type_expression) : (I.type_expression) resul
let%bind x' = O.CMap.fold aux x (ok I.CMap.empty) in
ok @@ I.T_sum x'
| O.T_record x ->
let aux k v acc =
let aux k ({field_type ; michelson_annotation} : O.field_content) acc =
let%bind acc = acc in
let%bind v' = untype_type_expression v in
let%bind field_type = untype_type_expression field_type in
let v' = ({field_type ; field_annotation=michelson_annotation} : I.field_content) in
ok @@ I.LMap.add (unconvert_label k) v' acc in
let%bind x' = O.LMap.fold aux x (ok I.LMap.empty) in
ok @@ I.T_record x'

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@ -38,7 +38,8 @@ let rec type_expression_to_type_value : T.type_expression -> O.type_value = fun
P_constant (C_variant, List.map type_expression_to_type_value tlist)
| T_record kvmap ->
let () = failwith "fixme: don't use to_list, it drops the record keys, rows have a differnt kind than argument lists for now!" in
P_constant (C_record, T.LMap.to_list @@ T.LMap.map type_expression_to_type_value kvmap)
let tlist = List.map (fun ({field_type;_}:T.field_content) -> field_type) (T.LMap.to_list kvmap) in
P_constant (C_record, List.map type_expression_to_type_value tlist)
| T_arrow {type1;type2} ->
P_constant (C_arrow, List.map type_expression_to_type_value [ type1 ; type2 ])
@ -85,7 +86,8 @@ let rec type_expression_to_type_value_copypasted : I.type_expression -> O.type_v
P_constant (C_variant, List.map type_expression_to_type_value_copypasted tlist)
| T_record kvmap ->
let () = failwith "fixme: don't use to_list, it drops the record keys, rows have a differnt kind than argument lists for now!" in
P_constant (C_record, I.LMap.to_list @@ I.LMap.map type_expression_to_type_value_copypasted kvmap)
let tlist = List.map (fun ({field_type;_}:I.field_content) -> field_type) (I.LMap.to_list kvmap) in
P_constant (C_record, List.map type_expression_to_type_value_copypasted tlist)
| T_arrow {type1;type2} ->
P_constant (C_arrow, List.map type_expression_to_type_value_copypasted [ type1 ; type2 ])
| T_variable type_name -> P_variable (type_name) (* eird stuff*)
@ -184,7 +186,7 @@ let constructor
C_equation (t_arg , c_arg)
] , whole_expr
let record : T.type_expression T.label_map -> (constraints * T.type_variable) = fun fields ->
let record : T.field_content T.label_map -> (constraints * T.type_variable) = fun fields ->
let record_type = type_expression_to_type_value (T.t_record fields ()) in
let whole_expr = Core.fresh_type_variable () in
[C_equation (P_variable whole_expr , record_type)] , whole_expr

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@ -611,9 +611,10 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
let%bind m = I.CMap.fold aux m (ok O.CMap.empty) in
return (T_sum m)
| T_record m ->
let aux k v prev =
let aux k ({field_type;field_annotation}: I.field_content) prev =
let%bind prev' = prev in
let%bind v' = evaluate_type e v in
let%bind field_type = evaluate_type e field_type in
let v' = ({field_type;michelson_annotation=field_annotation} : O.field_content) in
ok @@ O.LMap.add (convert_label k) v' prev'
in
let%bind m = I.LMap.fold aux m (ok O.LMap.empty) in
@ -724,7 +725,7 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
let%bind r_tv = get_t_record prev.type_expression in
let%bind tv =
generic_try (bad_record_access property ae prev.type_expression ae.location)
@@ (fun () -> O.LMap.find (convert_label property) r_tv) in
@@ (fun () -> let ({field_type;_} : O.field_content) = O.LMap.find (convert_label property) r_tv in field_type) in
let location = ae.location in
ok @@ make_e ~location (E_record_accessor {record=prev; path=convert_label property}) tv e
in
@ -771,7 +772,8 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
ok (O.LMap.add (convert_label k) expr' prev)
in
let%bind m' = Stage_common.Helpers.bind_fold_lmap aux (ok O.LMap.empty) m in
return (E_record m') (t_record (O.LMap.map get_type_expression m') ())
let lmap = O.LMap.map (fun e -> ({field_type = get_type_expression e; michelson_annotation = None}:O.field_content)) m' in
return (E_record m') (t_record lmap ())
| E_record_update {record; path; update} ->
let path = convert_label path in
let%bind record = type_expression' e record in
@ -782,7 +784,7 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
| T_record record -> (
let field_op = O.LMap.find_opt path record in
match field_op with
| Some tv -> ok (tv)
| Some {field_type;_} -> ok field_type
| None -> failwith @@ Format.asprintf "field %a is not part of record %a" Ast_typed.PP.label path O.PP.type_expression wrapped
)
| _ -> failwith "Update an expression which is not a record"

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@ -45,7 +45,7 @@ let rec check_no_nested_bigmap is_in_bigmap e =
ok ()
| T_record elm ->
let es = LMap.to_list elm in
let%bind _ = bind_map_list (fun l -> check_no_nested_bigmap is_in_bigmap l) es in
let%bind _ = bind_map_list (fun {field_type;_} -> check_no_nested_bigmap is_in_bigmap field_type) es in
ok ()
| T_arrow { type1; type2 } ->
let%bind _ = check_no_nested_bigmap false type1 in

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@ -13,6 +13,12 @@ let cmap_sep value sep ppf m =
let cmap_sep_d x = cmap_sep x (tag " ,@ ")
let record_sep value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, v) = fprintf ppf "@[<h>%a -> %a@]" label k value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let expression_variable ppf (ev : expression_variable) : unit =
fprintf ppf "%a" Var.pp ev
@ -48,6 +54,7 @@ and type_operator :
| TC_map (k, v) -> Format.asprintf "Map (%a,%a)" f k f v
| TC_big_map (k, v) -> Format.asprintf "Big Map (%a,%a)" f k f v
| TC_michelson_or (l,_, r,_) -> Format.asprintf "Michelson_or (%a,%a)" f l f r
| TC_michelson_pair (l,_, r,_) -> Format.asprintf "Michelson_pair (%a,%a)" f l f r
| TC_arrow (k, v) -> Format.asprintf "arrow (%a,%a)" f k f v
| TC_contract te -> Format.asprintf "Contract (%a)" f te
in

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@ -62,6 +62,7 @@ let t_big_map ?loc key value : type_expression = make_t ?loc @@ T_operator (
let t_set ?loc key : type_expression = make_t ?loc @@ T_operator (TC_set key)
let t_contract ?loc contract : type_expression = make_t ?loc @@ T_operator (TC_contract contract)
let t_michelson_or ?loc l l_ann r r_ann : type_expression = make_t ?loc @@ T_operator (TC_michelson_or (l, l_ann, r, r_ann))
let t_michelson_pair ?loc l l_ann r r_ann : type_expression = make_t ?loc @@ T_operator (TC_michelson_pair (l, l_ann, r, r_ann))
(* TODO find a better way than using list*)
let t_operator ?loc op lst: type_expression result =

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@ -42,10 +42,10 @@ val ez_t_sum : ?loc:Location.t -> ( string * type_expression ) list -> type_expr
val t_function : ?loc:Location.t -> type_expression -> type_expression -> type_expression
val t_map : ?loc:Location.t -> type_expression -> type_expression -> type_expression
val t_michelson_or : ?loc:Location.t ->
type_expression ->
michelson_prct_annotation ->
type_expression -> michelson_prct_annotation -> type_expression
val t_michelson_or : ?loc:Location.t -> type_expression -> michelson_prct_annotation ->
type_expression -> michelson_prct_annotation -> type_expression
val t_michelson_pair : ?loc:Location.t -> type_expression -> michelson_prct_annotation ->
type_expression -> michelson_prct_annotation -> type_expression
val t_operator : ?loc:Location.t -> type_operator -> type_expression list -> type_expression result
val t_set : ?loc:Location.t -> type_expression -> type_expression

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@ -24,8 +24,9 @@ and type_operator =
| TC_set of type_expression
| TC_map of type_expression * type_expression
| TC_big_map of type_expression * type_expression
| TC_michelson_or of type_expression * michelson_prct_annotation * type_expression * michelson_prct_annotation
| TC_arrow of type_expression * type_expression
| TC_michelson_or of type_expression * michelson_prct_annotation * type_expression * michelson_prct_annotation
| TC_michelson_pair of type_expression * michelson_prct_annotation * type_expression * michelson_prct_annotation
and type_expression = {type_content: type_content; location: Location.t}

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@ -14,6 +14,13 @@ let cmap_sep value sep ppf m =
let cmap_sep_d x = cmap_sep x (tag " ,@ ")
let record_sep_t value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, {field_type;_}) = fprintf ppf "@[<h>%a -> %a@]" label k value field_type in
fprintf ppf "%a" (list_sep new_pp sep) lst
let expression_variable ppf (ev : expression_variable) : unit =
fprintf ppf "%a" Var.pp ev
@ -25,7 +32,7 @@ let rec type_expression' :
fun f ppf te ->
match te.type_content with
| T_sum m -> fprintf ppf "@[<hv 4>sum[%a]@]" (cmap_sep_d f) m
| T_record m -> fprintf ppf "{%a}" (record_sep f (const ";")) m
| T_record m -> fprintf ppf "{%a}" (record_sep_t f (const ";")) m
| T_tuple t -> fprintf ppf "(%a)" (list_sep_d f) t
| T_arrow a -> fprintf ppf "%a -> %a" f a.type1 f a.type2
| T_variable tv -> type_variable ppf tv
@ -65,7 +72,7 @@ and expression_content ppf (ec : expression_content) =
fprintf ppf "%a(%a)" constant c.cons_name (list_sep_d expression)
c.arguments
| E_record m ->
fprintf ppf "{%a}" (record_sep expression (const ";")) m
fprintf ppf "{%a}" (record_sep_expr expression (const ";")) m
| E_record_accessor ra ->
fprintf ppf "%a.%a" expression ra.record label ra.path
| E_record_update {record; path; update} ->

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@ -51,7 +51,9 @@ let t_record ?loc m : type_expression =
let lst = Map.String.to_kv_list m in
t_record_ez ?loc lst
let t_pair ?loc (a , b) : type_expression = t_record_ez ?loc [("0",a) ; ("1",b)]
let t_pair ?loc (a , b) : type_expression = t_record_ez ?loc [
("0",{field_type=a;michelson_annotation=None}) ;
("1",{field_type=b;michelson_annotation=None})]
let t_tuple ?loc lst : type_expression = t_record_ez ?loc (tuple_to_record lst)
let ez_t_sum ?loc (lst:((string * ctor_content) list)) : type_expression =

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@ -32,10 +32,10 @@ val t_variable : ?loc:Location.t -> string -> type_expression
val t_record : te_map -> type_expression
*)
val t_pair : ?loc:Location.t -> ( type_expression * type_expression ) -> type_expression
val t_tuple : ?loc:Location.t -> type_expression list -> type_expression
val t_tuple : ?loc:Location.t -> field_content list -> type_expression
val t_record : ?loc:Location.t -> type_expression Map.String.t -> type_expression
val t_record_ez : ?loc:Location.t -> (string * type_expression) list -> type_expression
val t_record : ?loc:Location.t -> field_content Map.String.t -> type_expression
val t_record_ez : ?loc:Location.t -> (string * field_content) list -> type_expression
val t_sum : ?loc:Location.t -> ctor_content Map.String.t -> type_expression
val ez_t_sum : ?loc:Location.t -> ( string * ctor_content ) list -> type_expression

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@ -10,7 +10,7 @@ end
type type_content =
| T_sum of ctor_content constructor_map
| T_record of type_expression label_map
| T_record of field_content label_map
| T_tuple of type_expression list
| T_arrow of arrow
| T_variable of type_variable
@ -21,6 +21,8 @@ and arrow = {type1: type_expression; type2: type_expression}
and ctor_content = {ctor_type : type_expression ; michelson_annotation : string option}
and field_content = {field_type : type_expression ; michelson_annotation : string option}
and type_operator =
| TC_contract of type_expression
| TC_option of type_expression

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@ -31,11 +31,11 @@ val t_variable : ?loc:Location.t -> string -> type_expression
(*
val t_record : te_map -> type_expression
*)
val t_pair : ?loc:Location.t -> ( type_expression * type_expression ) -> type_expression
val t_tuple : ?loc:Location.t -> type_expression list -> type_expression
val t_pair : ?loc:Location.t -> ( field_content * field_content ) -> type_expression
val t_tuple : ?loc:Location.t -> field_content list -> type_expression
val t_record : ?loc:Location.t -> type_expression Map.String.t -> type_expression
val t_record_ez : ?loc:Location.t -> (string * type_expression) list -> type_expression
val t_record : ?loc:Location.t -> field_content Map.String.t -> type_expression
val t_record_ez : ?loc:Location.t -> (string * field_content) list -> type_expression
val t_sum : ?loc:Location.t -> Types.ctor_content Map.String.t -> type_expression
val ez_t_sum : ?loc:Location.t -> ( string * Types.ctor_content ) list -> type_expression

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@ -31,6 +31,18 @@ let tuple_sep value sep ppf m =
let new_pp ppf (_, v) = fprintf ppf "%a" value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let record_sep_t value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, {field_type;_}) = fprintf ppf "@[<h>%a -> %a@]" label k value field_type in
fprintf ppf "%a" (list_sep new_pp sep) lst
let tuple_sep_t value sep ppf m =
assert (Helpers.is_tuple_lmap m);
let lst = Helpers.tuple_of_record m in
let new_pp ppf (_, {field_type;_}) = fprintf ppf "%a" value field_type in
fprintf ppf "%a" (list_sep new_pp sep) lst
(* Prints records which only contain the consecutive fields
0..(cardinal-1) as tuples *)
let tuple_or_record_sep value format_record sep_record format_tuple sep_tuple ppf m =
@ -38,11 +50,16 @@ let tuple_or_record_sep value format_record sep_record format_tuple sep_tuple pp
fprintf ppf format_tuple (tuple_sep value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep value (tag sep_record)) m
let tuple_or_record_sep_t value format_record sep_record format_tuple sep_tuple ppf m =
if Helpers.is_tuple_lmap m then
fprintf ppf format_tuple (tuple_sep_t value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep_t value (tag sep_record)) m
let list_sep_d x = list_sep x (tag " ,@ ")
let cmap_sep_d x = cmap_sep x (tag " ,@ ")
let tuple_or_record_sep_expr value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " ,@ "
let tuple_or_record_sep_type value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " *@ "
let tuple_or_record_sep_type value = tuple_or_record_sep_t value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " *@ "
let constant ppf : constant' -> unit = function
| C_INT -> fprintf ppf "INT"

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@ -54,13 +54,13 @@ let t_contract t ?loc ?s () : type_expression = make_t ?loc (T_operator (TC_cont
let t_record m ?loc ?s () : type_expression = make_t ?loc (T_record m) s
let make_t_ez_record ?loc (lst:(string * type_expression) list) : type_expression =
let lst = List.map (fun (x,y) -> (Label x, y) ) lst in
let lst = List.map (fun (x,y) -> (Label x, {field_type=y;michelson_annotation=None}) ) lst in
let map = LMap.of_list lst in
make_t ?loc (T_record map) None
let ez_t_record lst ?loc ?s () : type_expression =
let m = LMap.of_list lst in
t_record m ?loc ?s ()
let t_pair a b ?loc ?s () : type_expression = ez_t_record [(Label "0",a) ; (Label "1",b)] ?loc ?s ()
let t_pair a b ?loc ?s () : type_expression = ez_t_record [(Label "0",{field_type=a;michelson_annotation=None}) ; (Label "1",{field_type=b;michelson_annotation=None})] ?loc ?s ()
let t_map ?loc k v ?s () = make_t ?loc (T_operator (TC_map { k ; v })) s
let t_big_map ?loc k v ?s () = make_t ?loc (T_operator (TC_big_map { k ; v })) s
@ -150,7 +150,9 @@ let tuple_of_record (m: _ LMap.t) =
let opt = LMap.find_opt (Label (string_of_int i)) m in
Option.bind (fun opt -> Some (opt,i+1)) opt
in
Base.Sequence.to_list @@ Base.Sequence.unfold ~init:0 ~f:aux
let l = Base.Sequence.to_list @@ Base.Sequence.unfold ~init:0 ~f:aux in
List.map (fun {field_type;_} -> field_type) l
let get_t_tuple (t:type_expression) : type_expression list result = match t.type_content with
| T_record lst -> ok @@ tuple_of_record lst
@ -178,13 +180,14 @@ let get_t_function_full (t:type_expression) : (type_expression * type_expression
| _ -> ([],t)
in
let (input,output) = aux 0 t in
let input = List.map (fun (l,t) -> (l,{field_type = t ; michelson_annotation = None})) input in
ok @@ (t_record (LMap.of_list input) (),output)
let get_t_sum (t:type_expression) : ctor_content constructor_map result = match t.type_content with
| T_sum m -> ok m
| _ -> fail @@ Errors.not_a_x_type "sum" t ()
let get_t_record (t:type_expression) : type_expression label_map result = match t.type_content with
let get_t_record (t:type_expression) : field_content label_map result = match t.type_content with
| T_record m -> ok m
| _ -> fail @@ Errors.not_a_x_type "record" t ()
@ -306,14 +309,20 @@ let e_a_mutez n = make_e (e_mutez n) (t_mutez ())
let e_a_bool b = make_e (e_bool b) (t_bool ())
let e_a_string s = make_e (e_string s) (t_string ())
let e_a_address s = make_e (e_address s) (t_address ())
let e_a_pair a b = make_e (e_pair a b) (t_pair a.type_expression b.type_expression ())
let e_a_pair a b = make_e (e_pair a b)
(t_pair a.type_expression b.type_expression () )
let e_a_some s = make_e (e_some s) (t_option s.type_expression ())
let e_a_lambda l in_ty out_ty = make_e (e_lambda l) (t_function in_ty out_ty ())
let e_a_none t = make_e (e_none ()) (t_option t ())
let e_a_record r = make_e (e_record r) (t_record (LMap.map get_type_expression r) ())
let e_a_record r = make_e (e_record r) (t_record
(LMap.map
(fun t ->
let field_type = get_type_expression t in
{field_type ; michelson_annotation=None} )
r ) () )
let e_a_application a b = make_e (e_application a b) (get_type_expression b)
let e_a_variable v ty = make_e (e_variable v) ty
let ez_e_a_record r = make_e (ez_e_record r) (ez_t_record (List.map (fun (x, y) -> x, y.type_expression) r) ())
let ez_e_a_record r = make_e (ez_e_record r) (ez_t_record (List.map (fun (x, y) -> x, {field_type = y.type_expression ; michelson_annotation = None}) r) ())
let e_a_let_in binder expr body attributes = make_e (e_let_in binder expr body attributes) (get_type_expression body)

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@ -25,9 +25,9 @@ val t_option : type_expression -> ?loc:Location.t -> ?s:S.type_expression -> uni
val t_pair : type_expression -> type_expression -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val t_list : type_expression -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val t_variable : type_variable -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val t_record : type_expression label_map -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val t_record : te_lmap -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val make_t_ez_record : ?loc:Location.t -> (string* type_expression) list -> type_expression
val ez_t_record : ( label * type_expression ) list -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val ez_t_record : ( label * field_content ) list -> ?loc:Location.t -> ?s:S.type_expression -> unit -> type_expression
val t_map : ?loc:Location.t -> type_expression -> type_expression -> ?s:S.type_expression -> unit -> type_expression
val t_big_map : ?loc:Location.t -> type_expression -> type_expression -> ?s:S.type_expression -> unit -> type_expression
@ -65,7 +65,7 @@ val get_t_pair : type_expression -> ( type_expression * type_expression ) result
val get_t_function : type_expression -> ( type_expression * type_expression ) result
val get_t_function_full : type_expression -> ( type_expression * type_expression ) result
val get_t_sum : type_expression -> ctor_content constructor_map result
val get_t_record : type_expression -> type_expression label_map result
val get_t_record : type_expression -> field_content label_map result
val get_t_map : type_expression -> ( type_expression * type_expression ) result
val get_t_big_map : type_expression -> ( type_expression * type_expression ) result
val get_t_map_key : type_expression -> type_expression result

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@ -120,6 +120,11 @@ let bind_fold_lmap f init (lmap:_ LMap.t) =
LMap.fold aux lmap init
let bind_map_lmap f map = bind_lmap (LMap.map f map)
let bind_map_lmap_t f map = bind_lmap (
LMap.map
(fun ({field_type;_}) ->
f field_type)
map)
let bind_map_cmap f map = bind_cmap (CMap.map f map)
let bind_map_lmapi f map = bind_lmap (LMap.mapi f map)
let bind_map_cmapi f map = bind_cmap (CMap.mapi f map)
@ -137,7 +142,7 @@ let is_tuple_lmap m =
let get_pair m =
let open Trace in
match (LMap.find_opt (Label "0") m , LMap.find_opt (Label "1") m) with
| Some e1, Some e2 -> ok (e1,e2)
| Some {field_type=e1;_}, Some {field_type=e2;_} -> ok (e1,e2)
| _ -> simple_fail "not a pair"
let tuple_of_record (m: _ LMap.t) =
@ -165,3 +170,12 @@ let is_michelson_or (t: _ constructor_map) =
CMap.cardinal t = 2 &&
(CMap.mem (Constructor "M_left") t) &&
(CMap.mem (Constructor "M_right") t)
let is_michelson_pair (t: _ label_map) =
let l = LMap.to_list t in
List.fold_left
(fun prev {field_type=_;michelson_annotation} -> match michelson_annotation with
| Some _ -> true
| None -> prev)
false
l

View File

@ -377,7 +377,7 @@ let rec assert_type_expression_eq (a, b: (type_expression * type_expression)) :
let sort_lmap r' = List.sort (fun (Label a,_) (Label b,_) -> String.compare a b) r' in
let ra' = sort_lmap @@ LMap.to_kv_list ra in
let rb' = sort_lmap @@ LMap.to_kv_list rb in
let aux ((ka, va), (kb, vb)) =
let aux ((ka, {field_type=va;_}), (kb, {field_type=vb;_})) =
let%bind _ =
trace (different_types "records" a b) @@
let Label ka = ka in

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@ -20,7 +20,7 @@ type type_constant =
| TC_void
type te_cmap = ctor_content constructor_map
and te_lmap = type_expression label_map
and te_lmap = field_content label_map
and type_meta = ast_core_type_expression option
and type_content =
@ -43,6 +43,11 @@ and ctor_content = {
michelson_annotation : annot_option;
}
and field_content = {
field_type : type_expression;
michelson_annotation : annot_option;
}
and type_map_args = {
k : type_expression;
v : type_expression;

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@ -8,29 +8,8 @@ let constructor ppf (c:constructor') : unit =
let label ppf (l:label) : unit =
let Label l = l in fprintf ppf "%s" l
let record_sep value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, v) = fprintf ppf "@[<h>%a -> %a@]" label k value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let tuple_sep value sep ppf m =
assert (Helpers.is_tuple_lmap m);
let lst = Helpers.tuple_of_record m in
let new_pp ppf (_, v) = fprintf ppf "%a" value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
(* Prints records which only contain the consecutive fields
0..(cardinal-1) as tuples *)
let tuple_or_record_sep value format_record sep_record format_tuple sep_tuple ppf m =
if Helpers.is_tuple_lmap m then
fprintf ppf format_tuple (tuple_sep value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep value (tag sep_record)) m
let list_sep_d x = list_sep x (tag " ,@ ")
let tuple_or_record_sep_expr value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " ,@ "
let tuple_or_record_sep_type value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " *@ "
let constant ppf : constant' -> unit = function
| C_INT -> fprintf ppf "INT"
@ -200,6 +179,46 @@ module Ast_PP_type (PARAMETER : AST_PARAMETER_TYPE) = struct
fprintf ppf "%a" (list_sep new_pp sep) lst
let cmap_sep_d x = cmap_sep x (tag " ,@ ")
let record_sep value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, {field_type;_}) = fprintf ppf "@[<h>%a -> %a@]" label k value field_type in
fprintf ppf "%a" (list_sep new_pp sep) lst
let tuple_sep value sep ppf m =
assert (Helpers.is_tuple_lmap m);
let lst = Helpers.tuple_of_record m in
let new_pp ppf (_, {field_type;_}) = fprintf ppf "%a" value field_type in
fprintf ppf "%a" (list_sep new_pp sep) lst
let record_sep_expr value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, v) = fprintf ppf "@[<h>%a -> %a@]" label k value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let tuple_sep_expr value sep ppf m =
assert (Helpers.is_tuple_lmap m);
let lst = Helpers.tuple_of_record m in
let new_pp ppf (_,v) = fprintf ppf "%a" value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
(* Prints records which only contain the consecutive fields
0..(cardinal-1) as tuples *)
let tuple_or_record_sep_t value format_record sep_record format_tuple sep_tuple ppf m =
if Helpers.is_tuple_lmap m then
fprintf ppf format_tuple (tuple_sep value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep value (tag sep_record)) m
let tuple_or_record_sep_expr value format_record sep_record format_tuple sep_tuple ppf m =
if Helpers.is_tuple_lmap m then
fprintf ppf format_tuple (tuple_sep_expr value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep_expr value (tag sep_record)) m
let tuple_or_record_sep_expr value = tuple_or_record_sep_expr value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " ,@ "
let tuple_or_record_sep_type value = tuple_or_record_sep_t value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " *@ "
let rec type_expression' :
(formatter -> type_expression -> unit)

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@ -40,7 +40,7 @@ module Ast_generic_type (PARAMETER : AST_PARAMETER_TYPE) = struct
type type_content =
| T_sum of ctor_content constructor_map
| T_record of type_expression label_map
| T_record of field_content label_map
| T_arrow of arrow
| T_variable of type_variable
| T_constant of type_constant
@ -50,6 +50,8 @@ module Ast_generic_type (PARAMETER : AST_PARAMETER_TYPE) = struct
and ctor_content = {ctor_type : type_expression ; michelson_annotation : string option}
and field_content = {field_type : type_expression ; field_annotation : string option}
and type_operator =
| TC_contract of type_expression
| TC_option of type_expression

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@ -0,0 +1,8 @@
type inner_storage is michelson_pair(int,"one",nat,"two")
type storage is michelson_pair (string,"three",inner_storage,"four")
type return is list(operation) * storage
function main (const action : unit; const store : storage) : return is block {
const foo : storage = ("foo",(1,2n)) ;
} with ((nil : list(operation)), (foo: storage))